Integrated gallium nitride based DC-DC converter

ABSTRACT

An integrated DC-DC converter device includes a plurality of GaN transistor sets. A first set of the plurality of GaN transistor sets includes transistors with a first drain-to-source distance, and wherein a second of the plurality of GaN transistor sets includes transistors with a second drain-to-source distance that is greater than the first drain-to-source distance.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.62/508,498, filed on May 18, 2017 and titled “Integrated Gallium NitrideBased Power Conversion System on Chip”, the entire contents of which arehereby incorporated by reference herein.

BACKGROUND

Power supplies and power converters are used in a variety of electronicsystems. Electrical power is generally transmitted over long distancesas an alternating current (AC) signal. The AC signal is divided andmetered as desired for each business or home location, and is oftenconverted to direct current (DC) for use with individual electronicdevices or components. Modern electronic systems often employ devices orcomponents designed to operate using different DC voltages. Accordingly,different DC-DC converters, or a DC-DC converter that supports a widerange of output voltages, are needed for such systems.

There are many different DC-DC converter topologies. The availabletopologies differ with regard to the components used, the amount ofpower handled, the input voltage(s), the output voltage(s), efficiency,reliability, size and/or other characteristics. Like many electroniccomponents, ongoing innovation efforts for DC-DC converters involve areduction in size. This is largely due to market demand for smallcomponents and the availability of integrated circuit (IC) fabricationtechnology.

Although IC fabrication technology provides an excellent platform formanufacturing circuits with repeated components, there are unmetchallenges when it comes to manufacturing IC versions of DC-DCconverters. These challenges are present to the extent different typesof switches are needed to handle power conversion operations. This isbecause making different types of switches complicates, or makesunfeasible, the IC fabrication process. One way to deal with thesechallenges is to make separate IC DC-DC converters, each with a limitedinput voltage range and output voltage range. However, this solutiondoes not leverage IC fabrication technology efficiently in that multipleIC dies and/or packages are needed for electronic systems designed touse a wide range of DC voltages. Efforts to improve DC-DC convertertechnology are ongoing.

SUMMARY OF THE INVENTION

In accordance with at least one example of the disclosure, an integratedDC-DC converter device comprises a plurality of sets of GaN transistorsformed on a single substrate, wherein a first of the plurality oftransistor sets includes at least one GaN transistor with a firstdrain-to-source distance, and wherein a second of the plurality oftransistor sets includes at least one GaN transistor with a seconddrain-to-source distance that is greater than the first drain-to-sourcedistance.

BRIEF DESCRIPTION OF THE DRAWINGS

For a detailed description of various examples, reference will now bemade to the accompanying drawings in which:

FIG. 1 shows a DC-DC converter device in accordance with variousembodiments;

FIG. 2 shows a gallium nitride (GaN) transistor in accordance withvarious embodiments;

FIG. 3 shows a block diagram of a multi-stage DC-DC converter inaccordance with various embodiments;

FIGS. 4A and 4B show schematic diagrams of stage 1 DC-DC convertertopologies in accordance with various embodiments;

FIGS. 5A-5F show schematic diagrams of stage 2 DC-DC convertertopologies in accordance with various embodiments;

FIG. 6A shows a schematic diagram of a stage 3 DC-DC converter topologyin accordance with various embodiments;

FIG. 6B shows a top view of an integrated circuit with the DC-DCconverter topology of FIG. 6A in accordance with various embodiments;

FIG. 7 shows a perspective view of a system on chip (SoC) and relatedprinted circuit board (PCB) in accordance with various embodiments; and

FIGS. 8-12 show block diagrams of multi-stage DC-DC converter scenariosin accordance with various embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The disclosed embodiments are directed to integrated DC-DC converterdevices with GaN transistors having different source-to-drain distancesand blocking voltages. Use of GaN transistors with differentsource-to-drain distances and blocking voltages, as described herein,provides integrated DC-DC converter devices with increased voltageconversion ranges compared to existing architectures for integratedDC-DC converter devices.

In one embodiment, an integrated DC-DC converter device includes athree-stage DC-DC converter, where the three stages include GaNtransistors with different source-to-drain distances and blockingvoltages. In another embodiment, an integrated DC-DC converter deviceincludes a two-stage DC-DC converter, where the two stages include GaNtransistors with different source-to-drain distances and blockingvoltages. In yet another embodiment, an integrated DC-DC converterdevice includes a single stage DC-DC converter, where the single stageincludes GaN transistors with different source-to-drain distances andblocking voltages. In various embodiments, a one-stage, two-stage, orthree-stage integrated DC-DC converter with GaN transistors havingdifferent source-to-drain distances and blocking voltages can becombined with other DC-DC converter stages as desired.

In various embodiments, the disclosed integrated DC-DC converter devicesalso include control circuitry (e.g., gate drive components) and/orpassive components (e.g., resistors, capacitors, and/or inductors). Thecontrol circuitry and/or passive components included in an integratedDC-DC converter devices may be components of a single DC-DC converterstage or multiple DC-DC converter stages. Also, in at least someembodiments, disclosed integrated DC-DC converter devices includesisolation between GaN transistors with different source-to-draindistances and blocking voltages. For example, the isolation may includesilicon-on-insulator (SOI) isolation or substrate well isolation. Also,in at least some embodiments, disclosed integrated DC-DC converterdevices are packaged and/or include connection points to electricallyconnect integrated DC-DC converter devices to other electricalcomponents. As an example, an integrated DC-DC converter device mayinclude packaging, solder dots, and/or pins to connect differentportions of the integrated DC-DC converter device to a printed circuitboard (PCB) pads and/or other external components. To provide a betterunderstanding, various integrated DC-DC converter device options,scenarios, and details are described with reference to the figures asfollows.

FIG. 1 shows a DC-DC converter device 100 in accordance with variousembodiments. As shown, the DC-DC converter device 100 includes aplurality of GaN transistor sets 102A-102N, where each of the transistorsets 102A-102N includes respective GaN transistors with differentsource-to-drain distances and blocking voltages relative to othertransistor sets. For example, each of the GaN transistors 104A-104N ofthe transistor set 102A have approximately the same source-to-draindistance 105, which correlates to a desired blocking voltage. Meanwhile,each of the GaN transistors 106A-106N of the transistor set 102N haveanother source-to-drain distance 107 (larger than the source-to-draindistance 105), which correlates to another desired blocking voltage.Likewise, the other represented transistor sets have respectivetransistors with a distinct source-to-drain distance and blockingvoltage. In different embodiments, the number of transistor sets and thenumber of transistors in each set may vary. Thus, a given transistor setmay only have one transistor or may have many transistors depending onthe DC-DC converter topology or topologies represented by the DC-DCconverter device 100.

As shown in FIG. 1, the integrated DC-DC converter device 100 alsoincludes isolation 108A-108M that separate the different transistorssets 102A-102N. In different embodiments, the isolation 108A-108M may besilicon-on-insulator SOI isolation and/or substrate well isolation. Whenthe integrated DC-DC converter device 100 is operating, the isolation108A-108M prevents or reduces leakage current flow between adjacenttransistor sets.

The integrated DC-DC converter device 100 also includes controlcircuitry 110. In at least some embodiments, the control circuitry 110includes gate drive components that provide control signals for thetransistor sets 102A-102N. In some embodiments, the control circuitry110 for all of the transistor sets 102A-102N is consolidated in one areaof the integrated DC-DC converter device 100. In other embodiments, thecontrol circuitry 110 includes separate gate drive components for eachtransistor set 102A-102N or other transistor groupings. In oneembodiment, the control circuitry 110 includes gate drive components fora single DC-DC converter stage. In other embodiments, the controlcircuitry 110 includes gate drive components for multiple DC-DCconverter stages (e.g., two stages or three stages).

The integrated DC-DC converter device 100 also includes passivecomponents 112 such as resistors, capacitors, and inductors. Indifferent embodiments, the passive components 112 vary according to theDC-DC converter topology or topologies selected for the integrated DC-DCconverter device 100. In one embodiment, the passive components 112 arefor a single DC-DC converter stage. In other embodiments, the passivecomponents 112 are for multiple DC-DC converter stages (e.g., two stagesor three stages). In at least some embodiments, the passive components112 include smoothing inductors for one or more DC-DC converter stages.In at least some embodiments, the passive components 112 include inputcapacitors for one or more DC-DC converter stages. In at least someembodiments, the passive components 112 include output capacitors forone or more DC-DC converter stages. In other embodiments, inputcapacitors and/or output capacitors for one or more DC-DC converterstages are not included with the integrated DC-DC converter device 100.In such embodiments, input capacitors and/or output capacitors areexternal components selected by manufacturers that install theintegrated DC-DC converter device 100 as part of a larger electricalsystem. To facilitate use of the integrated DC-DC converter device 100as part of a larger electrical system, input connection points 120 andoutput connection points 130 are included with the integrated DC-DCconverter device 100. In different embodiments, the input connectionpoints 120 and output connection points 130 are connection points for asingle DC-DC converter stage or multiple DC-DC converter stages (e.g.,two or three stages). For example, in multi-stage DC-DC converterembodiments, outputs for different stages may stay on chip and/or maypass to external components via some of the output connection points130. Also, in multi-stage DC-DC converter embodiments, inputs fordifferent stages may be received internally or may be received via someof the input connection points 120.

FIG. 2 shows a GaN transistor topology 200 in accordance with variousembodiments. In at least some embodiments, the GaN transistor topology200 is used to fabricate the transistors in the transistor sets102A-102N introduced in FIG. 1. As shown, GaN transistor 200 includes asemiconductor substrate 202 (e.g., silicon) and an isolation layer 204(e.g., aluminum nitride) over the semiconductor substrate 202. A GaNlayer 206 is disposed over the isolation layer 204. A two-dimensionalelectron gas (2DEG) 208 is created at the top of the GaN layer 206, asshown.

GaN transistor 200, includes contacts for source (S) 210, a drain (D)212, and a gate (G) 214. In at least some embodiments, an electrongenerating layer 218, preferably aluminum gallium nitride (AlGaN), isdisposed over the GaN layer 206 at least in the area between the gate214 and the source 210, and the area between the gate 214 and the drain212. As shown, a dielectric layer 216 covers the gate 214 and extends tothe source 210 and the drain 212. In at least some embodiments, a fieldplate 222 coupled to the source 210 extends over part of the dielectriclayer 216, covering the gate 214.

The GaN transistor architecture 200 is a lateral transistorarchitecture. By varying the source-to-drain distance 207, the blockingvoltage of a transistor with architecture 200 can be adjusted.Adjustments in the blocking voltage for architecture 200 may beunderstood to be changes in the gate-to-drain distance rather than thesource-to-drain distance 207.

In operation, GaN-based transistors behave similarly to silicon-basedpower metal-oxide semiconductor field-effect transistors (MOSFETs). Inenhancement mode devices, a positive bias on the gate 214 relative tothe source 210 causes a field effect which attracts electrons thatcomplete a bidirectional channel between the drain 212 and the source210. Since the electrons are pooled, as opposed to being loosely trappedin a lattice, the resistance of this channel is quite low. When the biasis removed from the gate 214, the electrons under it are dispersed intothe GaN layer 206, recreating the depletion region, and once again,giving it the capability to block voltage.

FIG. 3 shows a block diagram of a multi-stage DC-DC converter 300 inaccordance with various embodiments. As shown, the multi-stage DC-DCconverter 300 includes a stage 1 converter 302, a stage 2 converter 312,and a stage 3 converter 322. More specifically, the stage 1 converter302 includes an input interface 304, a converter topology 306, and anoutput interface 308. Similarly, the stage 2 converter 312 includes aninput interface 314, a converter topology 316, and an output interface318. Also, the stage 3 converter 322 includes an input interface 324, aconverter topology 326, and an output interface 328. In variousembodiments, the converter topology 306 can be made using GaNtransistors with different source-to-drain distances and blockingvoltages as well as other components (e.g., control circuitry andpassive components). Likewise, the converter topology 316 can be madeusing GaN transistors with different source-to-drain distances andblocking voltages as well as other components (e.g., control circuitryand passive components). Likewise, the converter topology 326 can bemade using GaN transistors with different source-to-drain distances andblocking voltages as well as other components (e.g., control circuitryand passive components).

In operation, the stage 1 converter 302 receives an input signal 301(e.g., an AC or DC signal) at the input interface 304, which includespads, pins, or other connection points. The input signal 301 is conveyedvia the input interface 304 to the converter topology 306, which changesthe input signal 301 to an output signal 307 with different voltage andcurrent characteristics than the input signal 301. The output signal 307from the converter topology 306 is provided to the output interface 308(e.g., pads, pins, or other connection points), and is provided as aninput signal 311 to the stage 2 converter 312. In some embodiments, theinput signal 311 is also provided to a load (e.g., electronics designedto operate on a voltage level corresponding to the voltage level of theinput signal 311).

The stage 2 converter 312 receives the input signal 311 at the inputinterface 314, which includes pads, pins, or other connection points.The input signal 311 is conveyed via the input interface 314 to theconverter topology 316, which changes the input signal 311 to an outputsignal 317 with different voltage and current characteristics than theinput signal 311. The output signal 317 from the converter topology 316is provided to the output interface 318 (e.g., pads, pins, or otherconnection points), and is provided as an input signal 321 to the stage3 converter 322. In some embodiments, the input signal 321 is alsoprovided to a load (e.g., electronics designed to operate based on avoltage level corresponding to voltage level of the input signal 321).

The stage 3 converter 322 receives the input signal 321 at the inputinterface 324, which includes pads, pins, or other connection points.The input signal 321 is conveyed via the input interface 324 to theconverter topology 326, which changes the input signal 321 to an outputsignal 327 with different voltage and current characteristics than theinput signal 321. The output signal 327 from the converter topology 326is provided to the output interface 328 (e.g., pads, pins, or otherconnection points), and is provided as signal 331, which may be providedto a load (e.g., electronics designed to operate based on a voltagelevel corresponding to the voltage level of the signal 331) and/or toother converter stages.

In different embodiments, an integrated DC-DC converter device (seee.g., device 100) includes one or more of the stage 1 converter 302, thestage 2 converter 312, and the stage 3 converter 322. For multi-stageembodiments, some of the input interfaces and/or output interface may byomitted. Also, in different embodiments, the converter topologies 306,316, and 326 may vary. Without limitation to other embodiments, severalpreferred converter topologies are described below.

FIGS. 4A and 4B show schematic diagrams of stage 1 DC-DC convertertopologies (e.g., converter topology 306 in FIG. 3) in accordance withvarious embodiments. More specifically, FIG. 4A shows a schematicdiagram of an inductor/inductor/capacitor (LLC) resonant convertertopology 400. As shown, the LLC resonant converter topology 400 includesan input capacitor 402 that receives a stage 1 input voltage (V1 _(IN)).In the LLC resonant converter topology 400, V1 _(IN) is passed to aswitch arrangement 404 with a high-side transistor controlled by CTL1and a low-side transistor controlled by CTL2. A controller (i.e., gatedrive components) to provide the CTL1 and CTL2 signals is not shown. Theswitch arrangement 404 operates to selectively pass V+ or V− to an LLCcircuit 406, resulting in a resonant signal on both sides of transformer408. A rectification arrangement 410 (e.g., powertransistors/synchronous rectifiers) rectifies the signal on the outputside of transformer 408, resulting in a stage 1 output signal (V1_(OUT)) across an output capacitor 412.

FIG. 4B shows a schematic diagram of a boost power factor correction(PFC) topology 420. As shown, the PFC topology 420 includes an AC source422 coupled to a full bridge rectifier 422. The output of the bridgerectifier 422 is the stage 1 input voltage, V1 _(IN). V1 _(IN) isreceived by a boost PFC circuit 424 (an inductor, a transistor switchcontrolled by CTL3, and a power transistor/synchronous rectifier),resulting in a stage 1 output signal (V1 _(OUT)) across an outputcapacitor 426. A controller (i.e., gate drive components) to provide theCTL3 signal is not shown. In some embodiments, V1 _(OUT) for the PFCtopology 420 is provided to another stage 1 topology (e.g., topology400).

In different embodiments, an integrated DC-DC converter device (e.g.,device 100 of FIG. 1) includes the LLC resonant converter topology 400,where the input capacitor 402 and/or the output capacitor 412 areomitted (e.g., they may be external components in some embodiments).Additionally or alternatively, an integrated DC-DC converter device(e.g., device 100 of FIG. 1) includes the PFC topology 420, where the ACsource 422 is omitted (e.g., it is an external component). Also, anintegrated DC-DC converter device based on the PFC topology 420 may omitrectifier arrangement 422 and/or the output capacitor 426 (e.g., theymay be external components in some embodiments). In some embodiments, anintegrated DC-DC converter device includes a boost PFC circuit (e.g.,the boost PFC circuit 424) at the input side of an LLC resonant circuittopology (e.g., topology 400). In one example, the stage 1 converterreceives an input voltage of 400V and provides an output voltage of 48V.

FIGS. 5A-5F show schematic diagrams of stage 2 DC-DC convertertopologies in accordance with various embodiments. In FIG. 5A, a flybackconverter topology 500 is represented. As shown, the flyback convertertopology 500 includes an input capacitor 502 that receives a stage 2input voltage (V2 _(IN)). In the flyback converter topology 500, theoperation of the switch 504, which is controlled by a control signal(CTL4) from controller 503 (i.e., gate drive components), results in anAC signal on both sides of the transformer 506. The AC signal on theoutput side of the transformer 506 is rectified by a powertransistor/synchronous rectifier 507, and the rectified signal isreceived by an output capacitor 508. The voltage across the outputcapacitor 508 is the stage 2 output signal (V2 _(OUT)).

In FIG. 5B, a single transistor forward converter topology 510 isrepresented. As shown, the single transistor forward converter topology510 includes an input capacitor 512 that receives a stage 2 inputvoltage (V2 _(IN)). In the single transistor forward converter topology510, the operation of the switch 514, which is controlled by a controlsignal (CTL5) from controller 513 (i.e., gate drive components), resultsin an AC signal on both sides of the transformer 516. The AC signal onthe output side of the transformer 516 is rectified and/or smoothed byrectifier arrangement 517, and the rectified signal is received by anoutput capacitor 518. The voltage across the output capacitor 518 is thestage 2 output signal (V2 _(OUT)).

In FIG. 5C, a two transistor forward converter topology 520 isrepresented. As shown, the two transistor forward converter topology 520includes an input capacitor 522 that receives a stage 2 input voltage(V2 _(IN)). In the two transistor forward converter topology 520, theoperation of diodes 525A and 525B as well as the switches 524A and 524B,which are controlled by control signals (CTL6 and CTL7) from controller523 (i.e., gate drive components), results in an AC signal on both sidesof the transformer 526. The AC signal on the output side of thetransformer 526 is rectified and/or smoothed by rectifier arrangement527, and the rectified signal is received by an output capacitor 528.The voltage across the output capacitor 528 is the stage 2 output signal(V2 _(OUT)).

In FIG. 5D, a push-pull converter topology 530 is represented. As shown,the push-pull converter topology 530 includes an input capacitor 532that receives a stage 2 input voltage (V2 _(IN)). In the push-pullconverter topology 530, the operation of the switches 534A and 534B,which are controlled by control signals (CTL8 and CTL9) from controller533 (i.e., gate drive components), results in an AC signal on both sidesof the transformer 536. The AC signal on the output side of thetransformer 536 is rectified and/or smoothed by rectifier arrangement537, and the rectified signal is received by an output capacitor 538.The voltage across the output capacitor 538 is the stage 2 output signal(V2 _(OUT)).

In FIG. 5E, a half-bridge converter topology 540 is represented. Asshown, the half-bridge converter topology 540 includes an inputarrangement 542 (e.g., input capacitors and resistors) that receives astage 2 input voltage (V2 _(IN)). In the half-bridge converter topology540, the operation of diodes 545A and 545B, capacitor 541, and switches544A and 544B, which are controlled by control signals (CTL10 and CTL11)from controller 543 (i.e., gate drive components), results in an ACsignal on both sides of the transformer 546. The AC signal on the outputside of the transformer 546 is rectified and/or smoothed by rectifierarrangement 547, and the rectified signal is received by an outputcapacitor 548. The voltage across the output capacitor 548 is the stage2 output signal (V2 _(OUT)).

In FIG. 5F, a full-bridge converter topology 550 is represented. Asshown, the full-bridge converter topology 550 includes an inputcapacitor 542 that receives a stage 2 input voltage (V2 _(IN)). In thefull-bridge converter topology 550, the operation of switches 544A-544D,which are controlled by control signals (CTL12-CTL15) from controllers553A and 553B (i.e., gate drive components), results in an AC signal onboth sides of the transformer 556. The AC signal on the output side ofthe transformer 556 is rectified and/or smoothed by rectifierarrangement 557, and the rectified signal is received by an outputcapacitor 558. The voltage across the output capacitor 558 is the stage2 output signal (V2 _(OUT)).

In different embodiments, the integrated DC-DC converter device (e.g.,device 100 of FIG. 1) includes one of the stage 2 converter topologies500, 510, 520, 530, 540, or 550, where the respective input capacitorand/or the respective output capacitor may be omitted (e.g., they may beexternal components in some embodiments). In one example, the stage 2converter receives an input voltage of 48V and provides an outputvoltage of 12V.

FIG. 6A shows a schematic diagram of a stage 3 DC-DC converter topology600 in accordance with various embodiments. Specifically, the stage 3DC-DC converter topology 600 is a buck converter. As shown, the topology600 includes an input capacitor 602 that receives a stage 3 inputvoltage (V3 _(IN)). In the topology 600, the operation of switches 604Aand 604B, which are controlled by control signals (CTL16 and CTL17) fromcontroller 603 (i.e., gate drive components), results in V3+ or V3−being passed to an inductor 607. The inductor 607 smooths the signal,resulting in V3 _(OUT) across an output capacitor 608. If there are nosubsequent stages, V3 _(OUT) is provided to one or more loads.

In different embodiments, the integrated DC-DC converter device (e.g.,device 100 of FIG. 1) includes the stage 3 converter topology 600, wherethe input capacitor 602 and/or the output capacitor 608 may be omitted(e.g., they may be external components in some embodiments). In oneexample, stage 3 converter receives an input voltage of 12V and providesan output voltage of 1V.

In various embodiments, an integrated DC-DC converter device (e.g.,device 100 of FIG. 1) includes GaN transistors with differentsource-to-drain distances and blocking voltages, where the transistorsare part of a stage 1 converter topology (e.g., topologies 400 or 420).In other embodiments, an integrated DC-DC converter device (e.g., device100 of FIG. 1) includes GaN transistors with different source-to-draindistances and blocking voltages, where the transistors are part of astage 2 converter topology (e.g., topologies 500, 510, 520, 530, 540, or550). In other embodiments, an integrated DC-DC converter device (e.g.,device 100 of FIG. 1) includes GaN transistors with differentsource-to-drain distances and blocking voltages, wherein the transistorsare part of a stage 3 converter topology (e.g., topology 600). In someembodiments, the integrated DC-DC converter device (e.g., device 100 ofFIG. 1) includes GaN transistors with different source-to-draindistances and blocking voltages, where the transistors are part of amulti-stage converter (e.g., a combination of stage 1 and stage 2converter topologies, a combination of stage 2 and stage 3 convertertopologies, or a combination of stage 1, stage 2, and stage 3 convertertopologies).

FIG. 6B shows a top view of an integrated circuit 610 with the DC-DCconverter topology of FIG. 6A in accordance with various embodiments. Asshown, the integrated circuit 610 includes a first transistor layout614A corresponding to transistor 604A. The integrated circuit 610 alsoincludes a second transistor layout 614B corresponding to transistor604B. A controller layout 613 in integrated circuit 610 includescontroller 603 (i.e., gate drive components). Finally, an inductorlayout 617 includes inductor 607. The capacitors 602 and 608 representedin topology 600 are omitted from the integrated circuit 610. As desired,such capacitors can be connected to input and output connection points(not specifically designated) of the integrated circuit 610. Indifferent embodiments, the position and size of transistor layouts,controller layouts, and inductor layouts in an integrated circuit suchas integrated circuit 610 may vary. Further, in some embodiments, anintegrated circuit may include stage 1 or stage 2 converter componentsinstead of stage 3 converter components. Further, in some embodiments,an integrated circuit may include components for multiple stages (stages1-2, stages 2-3, stages 1-3, etc.).

FIG. 7 shows a perspective view 700 of a system on chip (SoC) device 702and related PCB 710. The SoC device 702 includes a single integratedcircuit with GaN transistors with different source-to-drain distancesand blocking voltages as described herein. The SoC device 702 includesan integrated circuit with a single stage converter (e.g., a stage 1converter, a stage 2 converter, a stage 3 converter, etc.), or amulti-stage converter (stages 1-2, stages 2-3, stages 1-3, etc.). Invarious embodiments, the SoC device 702 can be connected to othercomponents. For example, in some embodiments, the SoC device 702 is partof a SoC package 704 with solder dots 703 or other connection points.When aligned with corresponding pads 714 on a PCB 710, heat may beapplied to couple the solder dots 703 to the corresponding pads 714. Thepads 714 couple to traces and/or other components on the PCB 710, suchthat the SoC device 702 becomes part of a larger electronic system thatrelies on the SoC device 702 for DC-DC converter operations.

FIGS. 8-12 show block diagrams of multi-stage DC-DC converter scenariosin accordance with various embodiments. In the multi-stage DC-DCconverter scenario 800 of FIG. 8, a multi-stage converter SoC device 802with GaN transistors with different source-to-drain distances andblocking voltages is represented. More specifically, the multi-stageconverter SoC device 802 includes three converter stages 810, 830, and850. The stage 1 converter 810 includes a first integrated circuitportion 812 with a first transistor set 814, input connection points811, and output connection points 813. The transistors of the firsttransistor set 814 include at least one GaN transistor, each GaNtransistor having approximately the same source-to-drain distance as anyother transistor in the first transistor set 814. The stage 1 converter810 also includes a second integrated circuit portion 822 with a secondtransistor set 824, input connection points 821, and output connectionpoints 823. The transistors of the second transistor set 824 include atleast one GaN transistor, each GaN transistor having approximately thesame source-to-drain distance as any other transistor in the secondtransistor set 824, and having a shorter source-to-drain distance thaneach transistor of the first transistor set 814. In one example, eachtransistor of the first transistor set 814 has a blocking voltage ofapproximately 600-650V and each transistor of the second transistor set824 has a blocking voltage of approximately 100-200V. In this example,the stage 1 converter 810 can handle an input voltage of 400V andprovide an output voltage of 48V.

The stage 2 converter 830 includes a third integrated circuit portion832 with a third transistor set 834, input connection points 831 andoutput connection points 833. The transistors of the third transistorset 834 include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the third transistor set 834, and having a shorter source-to-draindistance than each transistor of the transistor sets 814 and 824. Thestage 2 converter 830 also includes a fourth integrated circuit portion842 with a fourth transistor set 844, input connection points 841 andoutput connection points 843. The transistors of the fourth transistorset 844 include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the fourth transistor set 844, and having a shorter source-to-draindistance than each transistor of the transistor sets 814, 824, and 834.In an example, each transistor of the third transistor set 834 has ablocking voltage of 80-100V and each transistor of the fourth transistorset 844 has a blocking voltage of 30-60V. In this example, the stage 2converter 830 can handle an input voltage of 48V and provide an outputvoltage of 12V.

The stage 3 converter 850 includes a fifth integrated circuit portion852 with a fifth transistor set 854, input connection points 851 andoutput connection points 853. The transistors of the fifth transistorset 854 include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the fifth transistor set 854, and having a shorter source-to-draindistance) than each transistor of the transistor sets 814, 824, 834, and844. In an example, each transistor of the fifth transistor set 854 hasa blocking voltage of 20-30V. In this example, the stage 3 converter 850can handle an input voltage of 12 and provide an output voltage of 1V.

In FIG. 8, the multi-stage converter SoC device 802 includes isolation818, 828, 838, and 848 (e.g., SOI isolation or substrate well isolation)between the different integrated circuit portions. More specifically,isolation 818 is between the first and second integrated circuitportions 812 and 822. Also, isolation 828 is between the second andthird integrated circuit portions 822 and 832. Also, isolation 838 isbetween the third and fourth integrated circuit portions 832 and 842.Finally, isolation 848 is between the fourth and fifth integratedcircuit portions 842 and 852.

In different embodiments of the multi-stage converter SoC device 802,the position and quantity of input and output connection points for eachof the integrated circuit portions 812, 822, 832, 842, and 852 may vary.As an example, if signals (e.g., V1 _(OUT), V2 _(OUT), V3 _(OUT)) are tobe output from the device 802 at each of the integrated circuit portions812, 822, 832, 842, and 852, then the multi-stage converter SoC device802 may include input and output connections points for each integratedcircuit portions 812, 822, 832, 842, and 852 as shown in FIG. 8.Alternatively, if signals (e.g., V1 _(OUT), V2 _(OUT), V3 _(OUT)) arenot output from the device 802 for each of the integrated circuitportions 812, 822, 832, 842, and 852, then the multi-stage converter SoCdevice 802 may omit some of the input and output connections points. Forexample, the output connection points 813, 823, 833, 843 and the inputconnection points 821, 831, 841, 851 are omitted in some embodiments(only the input connection points 811 and the output connection points853 are used to connect the multi-stage converter SoC device 802 toexternal components). Other variations are possible. In someembodiments, input and output connection points for each of theintegrated circuit portions 812, 822, 832, 842, and 852 are needed dueto the isolation 818, 828, 838, and 848. In other embodiments, one ormore of isolation 818, 828, 838, and 848 are omitted and/or themulti-stage converter SoC device 802 includes internal connectorsbetween adjacent integrated circuit portions.

In some embodiments, the multi-stage converter SoC device 802 alsoincludes control circuitry (e.g., gate drive components) and/or passivecomponents. Such control circuitry generates gate driver signals for thetransistor sets 814, 824, 834, 844, and 854. Meanwhile, the passivecomponents (e.g., resistors, capacitors, and inductors) included withthe multi-stage converter SoC device 802 may vary according to the DC-DCconverter topologies selected for stages 810, 830, 850 of themulti-stage converter SoC device 802.

In FIG. 9, a multi-stage converter scenario 900 with a stage 1 converter908, a stage 2 converter 928, and a stage 3 converter 948 isrepresented, where the stage 2 converter 928 includes a stage 2converter SoC device 930 with GaN transistors with differentsource-to-drain distances and blocking voltages. More specifically, thestage 1 converter 908 includes first stage 1 converter device 910 andsecond stage 1 converter device 920. The first stage 1 converter device910 includes an integrated circuit portion 912 with a transistor set914, input connection points 911 and output connection points 913.Similarly, the second stage 1 converter device 920 includes anintegrated circuit portion 922 with a transistor set 924, inputconnection points 921 and output connection points 923. The variousinput and output connection points 911, 913, 921, 923 enable the firststage 1 converter device 910 and the second stage 1 converter device 920to couple to each other and/or other components.

In some embodiments, the transistors of the transistor set 914 in thefirst stage 1 converter device 910 include at least one GaN transistor,each GaN transistor having approximately the same source-to-draindistance as any other transistor in the transistor set 914. In otherembodiments, the transistors of the transistor set 914 are silicontransistors. Further, in some embodiments, the transistors of thetransistor set 924 in the second stage 1 converter device 920 include atleast one GaN transistor, each GaN transistor having approximately thesame source-to-drain distance as any other transistor in the transistorset 924. In other embodiments, the transistors of the second transistorset 924 are silicon transistors. Regardless of the particular transistortype used, the transistor set 914 in the first stage 1 converter device910 includes transistors with a first blocking voltage (e.g., 600-650V)and the transistor set 924 in the second stage 1 converter device 920includes transistors with a second blocking voltage (e.g., 100-200V). Asan example, the stage 1 converter 908 can handle an input voltage of400V and provide an output voltage of 48V.

In the multi-stage converter scenario 900, the stage 2 converter 928includes a stage 2 converter SoC device 930 with a first integratedcircuit portion 932 and a second integrated circuit portion 942. Thefirst integrated circuit portion 932 includes a first transistor set934, input connection points 931, and output connection points 933.Similarly, the second integrated circuit portion 942 includes a secondtransistor set 944, input connection points 941, and output connectionpoints 943.

The transistors of the first transistor set 934 include at least one GaNtransistor, each GaN transistor having approximately the samesource-to-drain distance as any other transistor in the first transistorset 934. Meanwhile, the transistors of the second transistor set 944include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the second transistor set 944, and having a shorter source-to-draindistance) than each transistor of the first transistor set 934. In anexample, each transistor of the first transistor set 934 has a blockingvoltage of approximately 80-100V and each transistor of the secondtransistor set 944 has a blocking voltage of approximately 30-60V. Inthis example, the stage 2 converter 928 can handle an input voltage of48V and provide an output voltage of 12V.

In FIG. 9, the stage 2 converter SoC device 930 includes isolation 938,(e.g., SOI isolation or substrate well isolation) between the integratedcircuit portions 932 and 942. In different embodiments of the stage 2converter SoC device 930, the position and quantity of input and outputconnection points for each of the integrated circuit portions 932 and942 may vary. As an example, if signals (e.g., V2 _(OUT)) are to beoutput from the device 930 for each of the integrated circuit portions932 and 942, then the stage 2 converter SoC device 930 may include inputand output connections points for each of the integrated circuitportions 932 and 942 as shown in FIG. 9. Alternatively, if signals(e.g., V2 _(OUT)) are not to be output from the device 930 for each ofthe integrated circuit portions 932 and 942, then the stage 2 converterSoC device 930 may omit some of the input and output connections points.For example, the output connection points 933 and the input connectionpoints 941 are omitted in some embodiments (the input connection points931 and the output connection points 943 remain to couple the stage 2converter SoC device 930 to external components). In some embodiments,input and output connection points for each of the integrated circuitportions 932 and 942 are needed due to the isolation 938. In otherembodiments, isolation 938 is omitted and/or the stage 2 converter SoCdevice 930 includes internal connectors between the integrated circuitportions 932 and 942.

In the multi-stage converter scenario 900, the stage 3 converter 948includes a stage 3 converter device 950. The stage 3 converter device950 includes an integrated circuit portion 952 with a transistor set954, input connection points 951, and output connection points 953. Thetransistors of the transistor set 954 include at least one GaNtransistor, each GaN transistor having approximately the samesource-to-drain distance as any other transistor in the transistor set954. In other embodiments, the transistors of the transistor set 954 aresilicon transistors. Regardless of the particular transistorarchitecture used, the transistor set 954 includes transistors with aparticular blocking voltage (e.g., 20-30V). In an example, the stage 3converter 948 can handle an input voltage of 12V and provide an outputvoltage of 1V.

The stage 2 converter SoC device 930 may also be used in other DC-DCconverter scenarios. For example, in one DC-DC converter scenario, thestage 2 converter SoC device 930 is used alone (e.g., to handle an inputvoltage of 48V and provide an output voltage of 12V). In another DC-DCconverter scenario, the stage 2 converter SoC device 930 is used with astage 1 converter. In another DC-DC converter scenario, the stage 2converter SoC device 930 is used with a stage 3 converter.

In FIG. 10, a multi-stage converter scenario 1000 with a stage 1converter 1008, a stage 2 converter 1028, and a stage 3 converter 1048is represented. In the scenario 1000, the stage 1 converter 1008 employsa stage 1 converter SoC device 1010 with GaN transistors with differentsource-to-drain distances and blocking voltages. More specifically,stage 1 converter SoC device 1010 includes a first integrated circuitportion 1012 and a second integrated circuit portion 1022. The firstintegrated circuit portion 1012 includes a first transistor set 1014,input connection points 1011, and output connection points 1013.Similarly, the second integrated circuit portion 1022 includes a secondtransistor set 1024, input connection points 1021, and output connectionpoints 1023.

The transistors of the first transistor set 1014 include at least oneGaN transistor, each GaN transistor having approximately the samesource-to-drain distance as any other transistor in the first transistorset 1014. Meanwhile, the transistors of the second transistor set 1024include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the second transistor set 1024, and having a shorter source-to-draindistance) than each transistor of the first transistor set 1014. In anexample, each transistor of the first transistor set 1014 has a blockingvoltage of approximately 600-650V and each transistor of the secondtransistor set 1024 has a blocking voltage of approximately 100-200V. Inthis example, the stage 1 converter 1008 can handle an input voltage of400V and provide an output voltage of 48V.

In FIG. 10, the stage 1 converter SoC device 1010 includes isolation1018, (e.g., SOI isolation or substrate well isolation) between theintegrated circuit portions 1012 and 1022. In different embodiments ofthe stage 1 converter SoC device 1010, the position and quantity ofinput and output connection points for each of the integrated circuitportions 1012 and 1022 may vary. As an example, if signals (e.g., V1_(OUT)) are to be output from the device 1010 for each of the integratedcircuit portions 1012 and 1022, then the stage 1 converter SoC device1010 may include input and output connections points for each of theintegrated circuit portions 1012 and 1022 as shown in FIG. 10.Alternatively, if signals (e.g., V1 _(OUT)) are not to be output fromthe device 1010 for each of the integrated circuit portions 1012 and1022, then the stage 1 converter SoC device 1010 may omit some of theinput and output connections points. For example, the output connectionpoints 1013 and the input connection points 1021 are omitted in someembodiments (the input connection points 1011 and the output connectionpoints 1023 remain to couple the stage 1 converter SoC device 1010 toexternal components). In some embodiments, input and output connectionpoints for each of the integrated circuit portions 1012 and 1022 areneeded due to isolation 1018. In other embodiments, isolation 1018 isomitted and/or the stage 1 converter SoC device 1010 includes internalconnectors between the integrated circuit portions 1012 and 1022.

In the multi-stage converter scenario 1000, the stage 2 converter 1028includes a first stage 2 converter device 1030 and a second stage 2converter device 1040. The first stage 2 converter device 1030 includesan integrated circuit portion 1032 with a transistor set 1034, inputconnection points 1031 and output connection points 1033. Similarly, thesecond stage 1 converter device 1040 includes an integrated circuitportion 1042 with a transistor set 1044, input connection points 1041and output connection points 1043. The various input and outputconnection points 1031, 1033, 1041, and 1043 enable the first stage 2converter device 1030 and the second stage 2 converter device 1040 tocouple to each other and/or other components.

In some embodiments, the transistors of the transistor set 1034 in thefirst stage 2 converter device 1030 include at least one GaN transistor,each GaN transistor having approximately the same source-to-draindistance as any other transistor in the transistor set 1034. In otherembodiments, the transistors of the transistor set 1034 are silicontransistors. Further, in some embodiments, the transistors of thetransistor set 1044 in the second stage 2 converter device 1040 includeat least one GaN transistor, each GaN transistor having approximatelythe same source-to-drain distance as any other transistor in thetransistor set 1044. In other embodiments, the transistors of the secondtransistor set 1044 are silicon transistors. Regardless of theparticular transistor type used, the transistor set 1034 in the firststage 2 converter device 1030 includes transistors with a first blockingvoltage (e.g., 80-100V) and the transistor set 1044 in the second stage2 converter device 1040 includes transistors with a second blockingvoltage (e.g., 30-60V). In an example, the stage 2 converter 1028 canhandle an input voltage of 48V and provide an output voltage of 12V.

In the scenario 1000, the stage 3 converter 1048 includes the stage 3converter device 950 as described in FIG. 9. Thus, the same discussiongiven for the stage 3 converter device 950 in FIG. 9 applies to thescenario 1000 of FIG. 10. In different embodiments, the stage 1converter SoC device 1010 is used in other DC-DC converter scenarios.For example, in one DC-DC converter scenario, the stage 1 converter SoCdevice 1010 is used alone (e.g., to handle an input voltage of 400V andprovide an output voltage of 48V). In another DC-DC converter scenario,the stage 1 converter SoC device 1010 is used with a stage 2 converter.

In FIG. 11, a multi-stage converter scenario 1100 with a stage 1converter 1108, a stage 2 converter 1128, and a stage 3 converter 1148is represented. In scenario 1100, the stage 2 converter 1128 and thestage 3 converter 1148 correspond to a multi-stage converter SoC device1130 with GaN transistors with different source-to-drain distances andblocking voltages. Meanwhile, the stage 1 converter 1108 includes thefirst stage 1 converter device 910 and second stage 1 converter device920 described in FIG. 9. Accordingly, the same discussion as given inFIG. 9 for the first stage 1 converter device 910 and second stage 1converter device 920 applies in the scenario 1100 of FIG. 11.

In scenario 1100, the multi-stage converter SoC device 1130 includes thestage 2 converter 1128 and the stage 3 converter 1148. The stage 2converter 1128 includes a first integrated circuit portion 1132 with afirst transistor set 1134, input connection points 1131, and outputconnection points 1133. The transistors of the first transistor set 1134include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the first transistor set 1134. The stage 2 converter 1128 alsoincludes a second integrated circuit portion 1142 with a secondtransistor set 1144, input connection points 1141, and output connectionpoints 1143. The transistors of the second transistor set 1144 includeat least one GaN transistor, each GaN transistor having approximatelythe same source-to-drain distance as any other transistor in the secondtransistor set 1144, and having a shorter source-to-drain distance thaneach transistor of the first transistor set 1134. In one example, eachtransistor of the first transistor set 1134 has a blocking voltage ofapproximately 80-100V and each transistor of the second transistor set1144 has a blocking voltage of approximately 30-60V. In this example,the stage 2 converter 1128 can handle an input voltage of 48V andprovide an output voltage of 12V.

The stage 3 converter 1148 includes a third integrated circuit portion1152 with a third transistor set 1154, input connection points 1151, andoutput connection points 1153. The transistors of the third transistorset 1154 include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the third transistor set 1154, and having a shorter source-to-draindistance than each transistor of the transistor sets 1134 and 1144. Inan example, each transistor of the third transistor set 1154 has ablocking voltage of 20-30V. In this example, the stage 3 converter 1148can handle an input voltage of 12V and provide an output voltage of 1V.

In FIG. 11, the multi-stage converter SoC device 1130 includes isolation1138 and 1148 (e.g., SOI isolation or substrate well isolation) betweenthe different integrated circuit portions. More specifically, isolation1138 is between the first and second integrated circuit portions 1132and 1142. Also, isolation 1148 is between the second and thirdintegrated circuit portions 1142 and 1152.

In different embodiments of the multi-stage converter SoC device 1130,the position and quantity of input and output connection points for eachof the integrated circuit portions 1132, 1142, and 1152 may vary. As anexample, if signals (e.g., V2 _(OUT), V3 _(OUT)) are to be output fromthe device 1130 at each of the integrated circuit portions 1132, 1142,and 1152, then the multi-stage converter SoC device 1130 may includeinput and output connections points for each integrated circuit portions1132, 1142, and 1152 as shown in FIG. 11. Alternatively, if signals(e.g., V2 _(OUT), V3 _(OUT)) are not output from the device 1130 foreach of the integrated circuit portions 1132, 1142, and 1152, then themulti-stage converter SoC device 1130 may omit some of the input andoutput connections points. For example, the output connection points1133, 1143 and the input connection points 1141, 1151 are omitted insome embodiments (only the input connection points 1131 and the outputconnections points 1153 are used to connect the multi-stage converterSoC device 1130 to external components). Other variations are possible.In some embodiments, input and output connection points for each of theintegrated circuit portions 1132, 1142, and 1152 are needed due to theisolation 1138 and 1148. In other embodiments, one or more of isolation1138 and 1148 is omitted and/or the multi-stage converter SoC device1130 includes internal connectors between adjacent integrated circuitportions.

In some embodiments, the multi-stage converter SoC device 1130 alsoincludes control circuitry (e.g., gate drive components) and/or passivecomponents. Such control circuitry generates gate driver signals for thetransistor sets 1134, 1144, and 1154. Meanwhile, the passive components(e.g., resistors, capacitors, and inductors) included with themulti-stage converter SoC device 1130 may vary according to the DC-DCconverter topologies selected for stages 1128 and 1148 of themulti-stage converter SoC device 1130. In some embodiments, themulti-stage converter SoC device 1130 is used alone (e.g., without astage 1 converter).

In FIG. 12, a multi-stage converter scenario 1200 with a stage 1converter 1208, a stage 2 converter 1228, and a stage 3 converter 1248is represented. In scenario 1200, the stage 1 converter 1208 and thestage 2 converter 1228 correspond to a multi-stage converter SoC device1210 with GaN transistors with different source-to-drain distances andblocking voltages. Meanwhile, the stage 3 converter 1248 includes thestage 3 converter device 950 described in FIG. 9. Accordingly, the samediscussion as given in FIG. 9 for the stage 3 converter device 950applies in the scenario 1200 of FIG. 12.

In scenario 1200, the multi-stage converter SoC device 1210 includes thestage 1 converter 1208 and the stage 2 converter 1228. The stage 1converter 1208 includes a first integrated circuit portion 1212 with afirst transistor set 1214, input connection points 1211, and outputconnection points 1213. The transistors of the first transistor set 1214include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the first transistor set 1214. The stage 1 converter 1208 alsoincludes a second integrated circuit portion 1222 with a secondtransistor set 1224, input connection points 1221, and output connectionpoints 1223. The transistors of the second transistor set 1224 includeat least one GaN transistor, each GaN transistor having approximatelythe same source-to-drain distance as any other transistor in the secondtransistor set 1224, and having a shorter source-to-drain distance thaneach transistor of the first transistor set 1214. In an example, eachtransistor of the first transistor set 1214 has a blocking voltage ofapproximately 600-650V and each transistor of the second transistor set1224 has a blocking voltage of approximately 100-200V. In this example,the stage 1 converter 1208 can handle an input voltage of 400V andprovide an output voltage of 48V.

The stage 2 converter 1228 includes a third integrated circuit portion1232 with a third transistor set 1234, input connection points 1231, andoutput connection points 1233. The transistors of the third transistorset 1234 include at least one GaN transistor, each GaN transistor havingapproximately the same source-to-drain distance as any other transistorin the third transistor set 1234, and having a shorter source-to-draindistance than each transistor of the transistor sets 1214 and 1224. Inan example, each transistor of the third transistor set 1234 has ablocking voltage of 80-100V.

The stage 2 converter 1228 also includes a fourth integrated circuitportion 1242 with a fourth transistor set 1244, input connection points1241, and output connection points 1243. The transistors of the fourthtransistor set 1244 include at least one GaN transistor, each GaNtransistor having approximately the same source-to-drain distance as anyother transistor in the third transistor set 1244, and having a shortersource-to-drain distance than each transistor of the transistor sets1214, 1224, and 1234. In an example, each transistor of the fourthtransistor set 1244 has a blocking voltage of 30-60V. In this example,the stage 2 converter 1228 can handle an input voltage of 48V andprovide an output voltage of 12V.

In FIG. 12, the multi-stage converter SoC device 1210 includes isolation1218, 1226, and 1238 (e.g., SOI isolation or substrate well isolation)between the different integrated circuit portions. More specifically,isolation 1218 is between the first and second integrated circuitportions 1212 and 1222. Also, isolation 1226 is between the second andthird integrated circuit portions 1222 and 1232. Finally, isolation 1238is between the third and fourth integrated circuit portions 1232 and1242.

In different embodiments of the multi-stage converter SoC device 1210,the position and quantity of input and output connection points for eachof the integrated circuit portions 1212, 1222, 1232, and 1242 may vary.As an example, if signals (e.g., V1 _(OUT), V2 _(OUT)) are to be outputfrom the device 1210 at each of the integrated circuit portions 1212,1222, 1232, and 1242, then the multi-stage converter SoC device 1210 mayinclude input and output connections points for each integrated circuitportions 1212, 1222, 1232, and 1242 as shown in FIG. 12. Alternatively,if signals (e.g., V1 _(OUT), V2 _(OUT)) are not output from the device1210 for each of the integrated circuit portions 1212, 1222, 1232, and1242, then the multi-stage converter SoC device 1210 may omit some ofthe input and output connections points. For example, the outputconnection points 1213, 1223, and 1233, and the input connection points1221, 1231, and 1241 are omitted in some embodiments (only the inputconnection points 1211 and the output connections points 1243 are usedto connect the multi-stage converter SoC device 1210 to externalcomponents). Other variations are possible. In some embodiments, inputand output connection points for each of the integrated circuit portions1212, 1222, 1232, and 1242, are needed due to isolation 1218, 1226,1238. In other embodiments, one or more of isolation 1218, 1226, 1238 isomitted and/or the multi-stage converter SoC device 1210 includesinternal connectors between adjacent integrated circuit portions.

In some embodiments, the multi-stage converter SoC device 1210 alsoincludes control circuitry (e.g., gate drive components) and/or passivecomponents. Such control circuitry generates gate driver signals for thetransistor sets 1214, 1224, 1234, 1244. Meanwhile, the passivecomponents (e.g., resistors, capacitors, and inductors) included withthe multi-stage converter SoC device 1210 may vary according to theDC-DC converter topologies selected for stages 1208 and 1228 of themulti-stage converter SoC device 1210.

In scenario 1200, the stage 3 converter 1248 includes the stage 3converter device 950 as described in FIG. 9. Thus, the same discussiongiven for the stage 3 converter device 950 in FIG. 9 applies to thescenario 1200 of FIG. 12. In different embodiments, the multi-stageconverter SoC device 1210 is used in other DC-DC converter scenarios.For example, in one DC-DC converter scenario, the multi-stage converterSoC device 1210 is used alone (e.g., to handle an input voltage of 400Vand provide an output voltage of 12V).

The above discussion is meant to be illustrative of the principles andvarious embodiments of the present disclosure. Numerous variations andmodifications will become apparent to those skilled in the art once theabove disclosure is fully appreciated. It is intended that the followingclaims be interpreted to embrace all such variations and modifications.

What is claimed is:
 1. An integrated DC-DC converter device, comprising:a plurality of GaN transistor sets formed on a substrate, wherein afirst set of the plurality of GaN transistor sets includes transistorswith a first drain-to-source distance, and wherein a second set of theplurality of GaN transistor sets includes transistors with a seconddrain-to-source distance that is greater than the first drain-to-sourcedistance; and substrate well isolation between each of the plurality ofGaN transistor sets.
 2. The integrated DC-DC converter device of claim1, wherein a third set of the plurality of GaN transistor sets includestransistors with a third drain-to-source distance that is greater thanthe second drain-to-source distance.
 3. The integrated DC-DC converterdevice of claim 2, wherein a fourth set of the plurality of GaNtransistor sets includes transistors with a fourth drain-to-sourcedistance that is greater than the third drain-to-source distance.
 4. Theintegrated DC-DC converter device of claim 3, wherein a fifth set of theplurality of GaN transistor sets includes transistors with a fifthdrain-to-source distance that is greater than the fourth drain-to-sourcedistance.
 5. The integrated DC-DC converter device of claim 1, whereinthe plurality of GaN transistor sets are associated with a single stageof a multi-stage DC-DC converter.
 6. The integrated DC-DC converterdevice of claim 1, wherein the plurality of GaN transistor sets areassociated with multiple stages of a multi-stage DC-DC converter.
 7. Theintegrated DC-DC converter device of claim 1, further comprising gatedrive components for a single stage of a multi-stage DC-DC converter. 8.The integrated DC-DC converter device of claim 1, further comprisinggate drive components for multiple stages of a multi-stage DC-DCconverter.
 9. The integrated DC-DC converter device of claim 1, furthercomprising passive components for a single stage of a multi-stage DC-DCconverter.
 10. The integrated DC-DC converter device of claim 1, furthercomprising passive components for multiple stages of a multi-stage DC-DCconverter.
 11. An integrated DC-DC converter device, comprising: aplurality of GaN transistor sets formed on a substrate, wherein a firstset of the plurality of GaN transistor sets includes transistors with afirst drain-to-source distance, and wherein a second set of theplurality of GaN transistor sets includes transistors with a seconddrain-to-source distance that is greater than the first drain-to-sourcedistance; and silicon on insulator (SOI) isolation between each of theplurality of GaN transistor sets.
 12. The integrated DC-DC converterdevice of claim 11, wherein a third set of the plurality of GaNtransistor sets includes transistors with a third drain-to-sourcedistance that is greater than the second drain-to-source distance. 13.The integrated DC-DC converter device of claim 12, wherein a fourth setof the plurality of GaN transistor sets includes transistors with afourth drain-to-source distance that is greater than the thirddrain-to-source distance.
 14. The integrated DC-DC converter device ofclaim 13, wherein a fifth set of the plurality of GaN transistor setsincludes transistors with a fifth drain-to-source distance that isgreater than the fourth drain-to-source distance.
 15. The integratedDC-DC converter device of claim 11, wherein the plurality of GaNtransistor sets are associated with a single stage of a multi-stageDC-DC converter.
 16. The integrated DC-DC converter device of claim 11,wherein the plurality of GaN transistor sets are associated withmultiple stages of a multi-stage DC-DC converter.
 17. The integratedDC-DC converter device of claim 11, further comprising gate drivecomponents for a single stage of a multi-stage DC-DC converter.
 18. Theintegrated DC-DC converter device of claim 11, further comprising gatedrive components for multiple stages of a multi-stage DC-DC converter.19. The integrated DC-DC converter device of claim 11, furthercomprising passive components for a single stage of a multi-stage DC-DCconverter.
 20. The integrated DC-DC converter device of claim 11,further comprising passive components for multiple stages of amulti-stage DC-DC converter.